MD659Z - Hydraulic station - Google Patents

Abstract

The invention relates to water-power engineering, in particular to hydroelectric stations using the kinetic energy of the water flow.The hydraulic station comprises a platform (1), located on two floats (7), (8) and pivotally mounted on a shore pier. On the platform (1) are placed an electric generator (24), a hydraulic pump (23), a multiplier (19) and a rotor (9) with blades (13) with a hydrodynamic profile, on the periphery of which are placed guides (16), (17), (18 ). Each blade (13) is covered with a hydrodynamic shell and consisted of modules, formed of submodules with ribs. The blades (13) are provided on both sides of the shell with suction ports, placed on the height of the blades (13) in the zone of the impact edge and adjacent zone of the running edge. The suction ports are made in the form of slots interconnected on each side of the blade through separate longitudinal channels. The longitudinal channels at the end of the running edges are connected by vertical channels.

Description

The invention relates to hydropower, especially to hydropower plants that use the kinetic energy of the water flow.

A hydraulic station is known, which contains a platform, placed on two floats and anchored to the shore with the possibility of adjusting its position with respect to the level of the water flow through a metal frame structure and tie rods, equipped with tension regulators, also containing , placed on the platform and kinematically linked to each other, an electric generator, a hydraulic pump, a multiplier and a turbine, which includes a vertical shaft linked with the multiplier and to which horizontal bars with vanes with a hydrodynamic profile are radially fixed. Two guides are installed on the platform to orient the vanes depending on the water flow direction for the downstream and upstream areas of vane-fluid interaction [1].

The disadvantage is that, although the vanes are oriented in the direction of the water flow, the efficiency of the conversion of the kinetic energy of the water flow is reduced, because the torque at the turbine rotor shaft is added up from the torques formed only by the vanes that interact with the flow of water, located only in the upstream and downstream areas of the turbine rotor. At the same time, the construction of the plant does not allow the positioning of the vanes depending on the area of vane-fluid interaction and the flow rate of the water flow, which leads to the reduction of the conversion efficiency. This disadvantage decreases the efficiency of the conversion, because when the water flow speed exceeds a certain threshold, the hydraulic resistance to the rotation of the vanes increases.

The problem that the invention solves is to increase the efficiency of the conversion of the available hydropower potential of the flow by reducing the negative influence of the separation effect of the boundary layer at the vane-fluid interaction and, respectively, in increasing the amount of hydraulic energy converted annually and decreasing its cost.

The problem is solved by the fact that the hydropower plant contains a platform, placed on two floats and fixed hinged on a shore base, on the platform being placed an electric generator, a hydraulic pump and a multiplier, with which a vertical axis is connected, at the end of which a rotor with vanes with a hydrodynamic profile is mounted, some guides are located on the periphery of the rotor. The vanes are mounted in the rotor on the axles with the possibility of rotating around them, positioning themselves under a variable angle of attack, determined by the profile of the guides; each vane is covered with a hydrodynamic cover and made up of modules, made up of sub-modules with ribs, the modules being separated from each other by some screens to direct the flow of the fluid towards their chord, at the same time the vanes are equipped on both sides of the cover with suction ports, located on the height of the paddles in the area of the attack board and the area adjacent to the running board; the suction holes are made in the form of openings joined to each other on each side of the blade through separate longitudinal channels for the circulation of liquid between the area of the attack board and the area of the trailing board; the longitudinal channels on each profiled side of the sub-modules at the end of the running board are joined with some vertical channels.

The longitudinal channels can be placed two on each flange of the submodules, and the vertical channels can be made in the form of perforated pipes.

The vanes can be immovably fixed in the rotor under a constant angle of attack, and the suction holes, the longitudinal channels that join them and the vertical channels can be located only on the upper part of the vanes.

Equipping the rotor with vanes with a sorbent hydrodynamic profile with suction mouths located in the area of the leading edge and in the area adjacent to the trailing edge allows a certain amount of liquid to be absorbed through the openings in the cover of the blade in the area of the leading edge and the trailing edge, a fact that diminishes the influence of the separation effect of the boundary layer at the vane-fluid interaction.

Thus, the reduction of the negative influence of the boundary layer separation effect on the fluid flow along the blade chord leads to the increase of the hydrodynamic performance coefficient Cρ of the blade and, respectively, of the conversion efficiency.

The invention is explained by the drawings in fig. 1-4, which represent:

- fig. 1, the main scheme of the hydropower plant, front view;

- fig. 2, the overall view of the vane with screens to reduce the flow of the fluid along its height;

- fig. 3, the construction of the vane with sorbent hydrodynamic profile: a) submodule, b) vane;

- fig. 4, 3D view of the sorbent hydrodynamic profile vane.

The hydropower plant (fig. 1) contains a platform 1 hinged on a shore base by means of a resistance structure 2 and tie rods 3 and 4, located parallel to the plane of symmetry of the resistance structure 2 on both sides of it, as well as of tie rods 5 and 6 connected to two floats 7, 8, located on one side of the rotor 9. The latter is constituted by the central shaft 10 with a vertical axis, immovably fixed to it an odd number of horizontal bars 11, at the extremity of which are mounted axles 12 with paddles 13 with a hydrodynamic profile with the possibility of rotating them around the axles 12. On the end of the axles 12 are mounted a rod 14, equipped with two rotating bodies 15, located perpendicular to the chord of the paddles 13. The rotating bodies 15 engage under the action hydrodynamic forces with the surface of guides 16 located in the upstream area of the rotor, guides 17 located in the downstream area and guides 18 located in the upstream-downstream transition area. The rotating bodies 15 are mounted in the rods 14 in longitudinal channels with the possibility of moving them in the longitudinal direction perpendicular to the chord of the pallets 13. The guides 16 and 17 have a circular arc profile with the corresponding radii R1 and R2, and the guide 18 has a rectilinear profile.

A multiplier 19 is installed on the platform 1, the driving shaft of which is coupled with the central shaft 10 of the rotor with hydrodynamic profile blades 13. The driven shaft of the multiplier 19 by means of belt (or chain) transmissions 20, 21 and 22 is kinematically linked with the hydraulic pump 23 and, respectively, with the electric generator 24 with low speed permanent magnets.

The pallets 13 are assembled from modules 25, each consisting of sub-modules 26 with ribs, the number of sub-modules being determined by the height h of the module 25. The inner space of the sub-modules 26 is filled with expanded material 27, and the pallets 13 are covered with hydrodynamic cover 28 of composite material . The height of the modules 25 is determined from the relationship where ν is the speed of the flow, and the peripheral contour of the screens 32 is equidistant to the profile of the vanes equal to (0.02...0.06) l, where l is the length of the vane chord. The modules 25 are fixed rigidly to the axles 29 by means of annular wedges with lateral projections 30 and, additionally, to the axles 31, and screens 32 are installed between the modules 25 and on the lower and upper parts of the vane to direct the flow of the fluid along the chord of the vane .

The vanes 13 (fig. 1) have a sorbent hydrodynamic profile, each being equipped on both sides of the hydrodynamic shell 28 (fig. 3a) with suction ports 33 and 34 of the liquid under pressure, located in the area of the leading edge of the vane on its height and with suction ports 35 and 36, located in the area adjacent to the escape board.

The suction holes 33 and 34 and, respectively, 35 and 36 are made in the form of openings in the hydrodynamic shell 28 of the vane, joined to each other on each side of the vane by separate longitudinal channels 37 and 38 for the circulation of liquid between the leading edge area and running board area. The longitudinal channels 37 and 38, which join the suction ports 33 and 34 with the suction ports 35 and 36, are placed two each on both flanges of each sub-module 26, at the same time the longitudinal channels 37 and 38 on each profiled part of the sub-modules 26 at the extremity of the running board are joined with some vertical channels 39, made in the form of perforated pipes.

If the vanes 13 (fig. 1) are immovably fixed in the rotor 9 under a constant angle of attack, the suction holes 33 (fig. 3a) and 35, the longitudinal channel 37 that joins them and the vertical channels 39 are located only on the upper part of the pallet 13.

The hydropower plant works in the following way.

The rotor 9 (fig. 1) with the vanes 13 is placed in the water flow of the river. Their position relative to the river water level is ensured by the Archimedean force, which acts on the floats 7 and 8 and on the submersible part of the vanes 13. The vertical position of the rotor axis 9 is ensured by adjusting the length of the tie rods 3 and 4, and the position of the platform 1 in relation with the direction of the flow of water is ensured with the help of tie rods 5 and 6, connected with the resistance structure 2, in which the floats 7 and 8 are immovably mounted.

The flow of water flowing at speed ν interacts with the vanes 13 with hydrodynamic profile, developing directed hydrodynamic forces so that they force the vanes 13 to rotate around the central axis of the rotor 9, applying to it a certain summary torque M, formed by the contribution of each pallets.

The mechanical positioning of the vanes 13 in relation to the direction of the flow of water is carried out by means of the rods 14, immovably fixed on the axes 12 of the vanes 13, and the rotating bodies 15, which under the action of hydrodynamic forces roll by contact on the surface of the guides 16 , 17 and 18, thus orienting each vane 13 under a certain angle of attack α. The torque and rotational movement developed by the hydrodynamic forces applied to the vanes 13 are transmitted from the central axis of the rotor 9 through the multiplier 19 and transmissions through the belt (or chain) 20, 21 and 22 to the electric generator 24 and the hydraulic pump 23.

At the interaction of the water flow with the vanes 13 (fig. 1) with hydrodynamic sorbent profile, equipped on both sides of the hydrodynamic shell 28 (fig. 3b) with suction holes 33 and 34 of the liquid under pressure located in the area of the attack board and with suction holes 35 and 36 located in the area adjacent to the running board, a certain part of the fluid is absorbed through the suction holes and circulates through the longitudinal channels 37 and 38 between the areas of the running board and attack. The absorption of the fluid under different pressure through the suction holes (fig. 4) located in the leading and trailing edge areas leads to the reduction of the negative influence of the boundary layer separation phenomenon on the flow of the fluid along the chord of the vanes. Thus, the reduction of the negative influence of this phenomenon stimulates the increase of the hydrodynamic performance coefficient Cρ of the paddles and, respectively, the increase of the conversion efficiency of the available energy potential of the water currents into useful energy.

1. MD 3845 G2 2009.02.28

Claims (3)

1. Hydropower plant, which contains a platform (1), placed on two floats (7), (8) and hingedly fixed on a shore base, on the platform (1) being placed an electric generator (24), a hydraulic pump ( 23) and a multiplier (19), with which a vertical axis is connected, at the end of which is mounted a rotor (9) with vanes (13) with a hydrodynamic profile, on the periphery of the rotor (9) some guides (16) are placed, (17), (18), characterized by the fact that the vanes (13) are mounted in the rotor (9) on the axles (12) with the possibility of rotation around them, positioning themselves under a variable angle of attack, determined by the profile of the guides ( 16), (17), (18); each vane (13) is covered with a hydrodynamic cover (28) and consists of modules (25), formed by sub-modules (26) with ribs, the modules (25) being separated from each other by some screens (32) to direct the fluid flow towards the string them, at the same time the vanes (13) are equipped on both sides of the casing (28) with some suction ports (33), (34), (35), (36), located on the height of the vanes (13) in the area of the attack board and the area adjacent to the running board; the suction holes (33), (34), (35), (36) are executed in the form of openings joined together on each side of the blade through separate longitudinal channels (37), (38) for the circulation of liquid between the board area attack and runaway area; the longitudinal channels (37), (38) on each profiled part of the sub-modules (26) at the end of the running board are joined with some vertical channels (39). 2. Hydropower plant, according to claim 1, characterized in that the longitudinal channels (37), (38) are placed two on each flange of the submodules (26), and the vertical channels (39) are made in the form of perforated pipes. 3. Hydropower plant, according to claims 1 and 2, characterized in that the vanes (13) are immovably fixed in the rotor (9) under a constant angle of attack, and the suction ports, the longitudinal channels that join them and the vertical channels are located only on upper part of the vanes (13).